Quinones arylation

With the conformational information in hand, the fluorescence lifetimes of the dyad and triad species were determined in dichloromethane solution in order to extract rate constants for photoinitiated electron transfer (e.g., step 2 in Figure 4) via Eq. (1). The results are tabulated in Table 1. Also included in the table are the distances from the center of the porphyrin macrocycle to the center of the quinone aryl ring and the distances from the edge of the porphyrin macrocycle (the nearest porphyrin meso carbon atom) to the edge of the quinone aryl ring (the carbon atom bearing the methylene group) (r e)-... 

A more recent development in quinone chemistry has been the tandem reaction sequence. In seeking elegant syntheses of complex molecules, careful orchestration of transformations has become essential. The use of the Thiele-Winter reaction in tandem with arylation gives good yields of pharmacologically interesting heterocycles, such as (62), from 2,5-dihydroxy-l,4-ben2oquinone [615-94-1] and pyridines, where R = H or CH (60). 

Arylation of enamines with p-benzoquinones takes a somewhat different course (70). The enamine (16) reacts exothermally with p-benzoquinone in benzene solution to give 2-(dimethylamino)-2,3-dihydro-3,3-dimethyl-5-benzofuranol (92). The reaction of enamines with quinone dibenzenesul-fonimide proceeds similarly (68). The product from the enamine (28) is the tetrahydrocarbazole derivative (93). 

The reactions of enamines with positively activated olefins have been extended to arylations with />-quinones (350,362-369) and quinone sulfoni-mides (365-368,370). Thus a new pathway for the facile formation of benzofurans and indoles became available. 

The Gomberg-Bachmann reaction is a method for arylation of aromatic compounds and quinones (Gomberg and Bachmann, 1924). Originally this reaction involved adding aqueous sodium hydroxide slowly to an intimate mixture of an aqueous solu-... 

This reaction is most often carried out with R = aryl, so the net result is the same as in 14-17, though the reagent is different. It is used less often than 14-17, but the scope is similar. When R = alkyl, the scope is more limited. Only certain aromatic compounds, particularly benzene rings with two or more nitro groups, and fused ring systems, can be alkylated by this procedure. 1,4-Quinones can be alkylated with diacyl peroxides or with lead tetraacetate (methylation occurs with this reagent). 

Quinone methides formed during, for example, alkaline pulping reactions may have other mechanisms for rearomatization. Most commonly, in 8-0-4-, 8-5-, and 8-8-quinone methides QM1-QM3 (Fig. 12.2), retro-aldol elimination of formaldehyde to give styryl aryl ethers or stilbenes is common.40 Retro-aldol reactions using a strong base, for example, diazabicycloundecene (DBU) in CH2CI2 can also provide these compounds conveniently at room temperatures.41 3... 

The quinone methide can also be generated in situ, at least in aqueous NaOH, directly from the peracetate, as hydrolysis of the phenolic acetate is faster than the benzylic acetate (see an example in Section 12.5.3). This method was used to demonstrate the addition of anthrahydroquinone (AHQ) and anthranol to (actual polymeric) lignin quinone methides in studies elucidating the anthraquinone (AQ)-catalyzed 8-0-4-aryl ether cleavage mechanisms in alkaline pulping.64-66... 

Quinone methides are electron-deficient at C7, as readily understood via the resonance forms of QM1 shown in Fig. 12.7. They are therefore susceptible to nucleophilic attack at that position. Although reactions during high-temperature pulping demonstrate that 8-<9-4-aryl ether quinone methides QM1 are rearomatized by attack with hard nucleophiles such as HO- and HS, 81 these reactions do not readily occur at ambient temperatures.41,85 Thus, HO will not add to quinone methide QM1 under any conditions that we have tried (including with cosolvents, and using phase-transfer conditions). Of course water will add to quinone methides under acidic conditions... 

Ralph, J. Ede, R. M. Robinson, N. P. Main, L. Reactions of P-aryl lignin model quinone methides with anthrahydroquinone and anthranol. J. Wood Chem. Technol. 1987, 7, 133-160. 

The catalytic cycle of laccase includes several one-electron transfers between a suitable substrate and the copper atoms, with the concomitant reduction of an oxygen molecule to water during the sequential oxidation of four substrate molecules [66]. With this mechanism, laccases generate phenoxy radicals that undergo non-enzymatic reactions [65]. Multiple reactions lead finally to polymerization, alkyl-aryl cleavage, quinone formation, C> -oxidation or demethoxylation of the phenolic reductant [67]. 

Stannyl groups attached to quinones can be displaced by aryl, heteryl and other groups, as shown in reactions 32286 and 67314. 

Although treated as separate classes in the Colour Index, these structural types are closely related and the few diphenylmethane dyes such as auramine (1.28 Cl Basic Yellow 2) are now of little practical interest. Commercial usage of the triarylmethane dyes and pigments has also declined considerably in favour of the major chemical classes. They were formerly noteworthy contributors to the acid, basic, mordant and solvent ranges, primarily in the violet, blue and green sectors. Numerous structural examples are recorded in the Colour Index. The terminal groupings can be amine/quinonimine, as in auramine and crystal violet (1.29 Cl Basic Violet 3), hydroxy/quinone, or both. The aryl nuclei are not always benzenoid (section 6.5). 

Complex iron(III) salts are frequently used in oxidative arene coupling reactions and quinone formation and tetra-n-butylammonium hexacyanoferrate(III) has several advantages in it use over more conventional oxidative procedures. When used as the dihydrogen salt, Bu4N[H2Fe(CN)6], it oxidizes 2,6-di-z-buty 1-4-methylphenol (1) to the coupled diarylethane (2), or aryl ethers (3) and (4) (Scheme 10.4), depending on the solvent. It is noteworthy that no oxidation occurs even after two days with the tris-ammonium salt. 

The anodic coupling of aryl ethers is reviewed in Ref. [180]. Aryl ethers are more selectively coupled than phenols for the following reasons The carbon-oxygen coupling is made impossible and the ortho-coupling and the oxidation to quinones become more difficult. A mixture of triflu-oroacetic acid (TFA) and dichloromethane proved to be the most suitable electrolyte [181]. TFA enhances the radical cation stability and suppresses the nucle-ophilicity of water. Of further advantage is the addition of alumina or trifluo-roacetic anhydride [182]. Table 12 compiles representative examples of the aryl ether coupling. 

Popp BV, Stahl SS (2007) Palladium-Catalyzed Oxidation Reactions Comparison of Benzo-quinone and Molecular Oxygen as Stoichiometric Oxidants. 22 149-189 Prashad M (2004) Palladium-Catalyzed Heck Arylations in the Synthesis of Active Pharmaceutical Ingredients. 6 181-204 Prestipino C, see Zecchina A (2005) 16 1-35 Pretraszuk C, see Marciniec B (2004) 11 197-248... 

These findings led to the proposition that the veratryl alcohol is degraded via the quinone intermediates (Figure 5) to CO2 through a series of transformations involving lignin peroxidase, perhydroxy radicals and the NADP-dependent aryl alcohol oxidoreductase. Veratraldehyde, the major product of lignin peroxidase catalyzed veratryl alcohol oxidation, is rapidly reduced back to veratryl alcohol it is the further metabolism of the side products of the oxidative process, viz. the quinones and lactones, that drives the overall transformation towards completion (34). 

A second example from the same group is the synthesis of an elaborate diethynyltriphenylene derivative (Scheme 7 Table 8,entries 12,13) [58].Zn/Pd-promoted homocoupling of a 4-iodo-l,2-dialkoxybenzene furnishes the desired tetraalkoxybiphenyl, an electron-rich aromatic system. Iron trichloride-catalyzed Friedel-Crafts arylation of the biphenyl derivative with dimethoxy-benzene furnishes an unsymmetrical triphenylene derivative. Deprotection, oxidation, and subsequent Diels-Alder reaction with cyclohexadiene is followed by catalytic hydrogenation and reoxidation. TMS-CC-Li attack on the quinone delivers the alkyne modules, treatment with SnCl2 aromatizes the six-mem-bered ring, while KOH in MeOH removes the TMS groups cleanly to give the elaborate monomer. 

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